Difference between revisions of "Applets:Periodendauer periodischer Signale"
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− | + | <p> | |
+ | {{BlaueBox|TEXT= | ||
+ | <B style="font-size:18px">Funktion:</B> | ||
+ | $$x(t) = A_1\cdot cos\Big(2\pi f_1\cdot t- \frac{2\pi}{360}\cdot \phi_1\Big)+A_2\cdot cos\Big(2\pi f_2\cdot t- \frac{2\pi}{360}\cdot \phi_2\Big)$$ | ||
+ | }} | ||
+ | </p> | ||
<html> | <html> | ||
Line 34: | Line 39: | ||
<div id="cnfBoxHtml" class="jxgbox" style="width:600px; height:150px; float:top; margin:-10px 20px 100px 0px;"></div> | <div id="cnfBoxHtml" class="jxgbox" style="width:600px; height:150px; float:top; margin:-10px 20px 100px 0px;"></div> | ||
<div id="pltBoxHtml" class="jxgbox" style="width:600px; height:600px; border:1px solid black; margin:-100px 20px 10px 0px;"></div> | <div id="pltBoxHtml" class="jxgbox" style="width:600px; height:600px; border:1px solid black; margin:-100px 20px 10px 0px;"></div> | ||
+ | |||
+ | <!-- Ausgabefelder --> | ||
<table> | <table> | ||
Line 56: | Line 63: | ||
}); | }); | ||
pltBox = JXG.JSXGraph.initBoard('pltBoxHtml', { | pltBox = JXG.JSXGraph.initBoard('pltBoxHtml', { | ||
− | showCopyright: false, axis: | + | showCopyright: false, axis: false, |
zoom: { factorX: 1.1, factorY: 1.1, wheel: true, needshift: true, eps: 0.1 }, | zoom: { factorX: 1.1, factorY: 1.1, wheel: true, needshift: true, eps: 0.1 }, | ||
− | grid: | + | grid: false, boundingbox: [-0.5, 2.2, 12.4, -2.2] |
+ | }); | ||
+ | cnfBox.addChild(pltBox); | ||
+ | // Einstellungen der Achsen | ||
+ | xaxis = pltBox.create('axis', [[0, 0], [1, 0]], { | ||
+ | name: '$\\dfrac{t}{T}$', | ||
+ | withLabel: true, label: { position: 'rt', offset: [-25, -10] } | ||
+ | }); | ||
+ | yaxis = pltBox.create('axis', [[0, 0], [0, 1]], { | ||
+ | name: '$x(t)$', | ||
+ | withLabel: true, label: { position: 'rt', offset: [10, -5] } | ||
}); | }); | ||
− | + | // Erstellen der Schieberegler | |
+ | sldA1 = cnfBox.create('slider', [ [-0.7, 1.5], [3, 1.5], [0, 0.5, 1] ], { | ||
+ | suffixlabel: '$A_1=$', | ||
+ | unitLabel: 'V', snapWidth: 0.01 | ||
+ | }), | ||
+ | sldF1 = cnfBox.create('slider', [ [-0.7, 0.5], [3, 0.5], [0, 1, 10] ], { | ||
+ | suffixlabel: '$f_1=$', | ||
+ | unitLabel: 'kHz', snapWidth: 0.1 | ||
+ | }), | ||
+ | sldPHI1 = cnfBox.create('slider', [ [-0.7, -0.5], [3, -0.5], [-180, 0, 180] ], { | ||
+ | suffixlabel: '$\\phi_1=$', | ||
+ | unitLabel: 'Grad', snapWidth: 5 | ||
+ | }), | ||
+ | sldA2 = cnfBox.create('slider', [ [6, 1.5], [9.7, 1.5], [0, 0.5, 1] ], { | ||
+ | suffixlabel: '$A_2=$', | ||
+ | unitLabel: 'V', snapWidth: 0.01 | ||
+ | }), | ||
+ | sldF2 = cnfBox.create('slider', [ [6, 0.5], [9.7, 0.5], [0, 2, 10] ], { | ||
+ | suffixlabel: '$f_2=$', | ||
+ | unitLabel: 'kHz', snapWidth: 0.1 | ||
+ | }), | ||
+ | sldPHI2 = cnfBox.create('slider', [ [6, -0.5], [9.7, -0.5], [-180, 90, 180] ], { | ||
+ | suffixlabel: '$\\phi_2=$', | ||
+ | unitLabel: 'Grad', snapWidth: 5 | ||
+ | }), | ||
+ | sldT = cnfBox.create('slider', [ [-0.7, -1.5], [3, -1.5], [0, 0, 10] ], { | ||
+ | suffixlabel: '$t=$', | ||
+ | unitLabel: 's', snapWidth: 0.2 | ||
+ | }), | ||
+ | // Definition der Funktion | ||
+ | signaldarstellung = pltBox.create('functiongraph', [function(x) { | ||
+ | return (sldA1.Value() * Math.cos(2 * Math.PI * sldF1.Value() * x - 2 * Math.PI * sldPHI1.Value() / 360) + sldA2.Value() * Math.cos(2 * Math.PI * sldF2.Value() * x - 2 * Math.PI * sldPHI2.Value() / 360)) | ||
+ | }], { | ||
+ | strokeColor: "red" | ||
+ | }); | ||
+ | // Definition des Punktes p_T0, des Hilfspunktes p_T0h und der Geraden l_T0 für Periodendauer T_0 | ||
+ | p_T0 = pltBox.create('point', [ | ||
+ | function() { | ||
+ | return (Math.round(getT0() * 100) / 100); | ||
+ | }, | ||
+ | function() { | ||
+ | return sldA1.Value() * Math.cos(2 * Math.PI * sldF1.Value() * (Math.round(getT0() * 100) / 100) - 2 * Math.PI * sldPHI1.Value() / 360) + | ||
+ | sldA2.Value() * Math.cos(2 * Math.PI * sldF2.Value() * (Math.round(getT0() * 100) / 100) - 2 * Math.PI * sldPHI2.Value() / 360); | ||
+ | }], | ||
+ | { color: "blue", fixed: true, label: false, size: 1, name: '' } | ||
+ | ); | ||
+ | p_T0h = pltBox.create('point', | ||
+ | [function() { return (Math.round(getT0() * 100) / 100); }, 2], | ||
+ | { visible: false, color: "blue", fixed: true, label: false, size: 1, name: '' } | ||
+ | ); | ||
+ | l_T0 = pltBox.create('line', [p_T0, p_T0h]) | ||
+ | // Bestimmung des Wertes T_0 mit der Funktion von Siebenwirth | ||
+ | setInterval(function() { | ||
+ | document.getElementById("T_0").innerHTML = Math.round(getT0() * 100) / 100; | ||
+ | }, 50); | ||
+ | function isInt(n) { | ||
+ | return n % 1 === 0; | ||
+ | } | ||
+ | function getT0() { | ||
+ | var A, B, C, Q; | ||
+ | if (sldF1.Value() < sldF2.Value()) { | ||
+ | A = sldF1.Value(); | ||
+ | B = sldF2.Value(); | ||
+ | } else { | ||
+ | B = sldF1.Value(); | ||
+ | A = sldF2.Value(); | ||
+ | } | ||
+ | // console.log('Berechne T0 mit A=' + A, 'B=' + B); | ||
+ | for (var x = 1; x <= 100; x++) { | ||
+ | C = A / x; | ||
+ | Q = B / C; | ||
+ | // console.log(x + '. Durchgang: C = ' + C, 'Q = ' + Q); | ||
+ | if (isInt(Q)) { | ||
+ | // console.log('Q ist eine Ganzzahl!!! T0 ist damit ', 1 / C); | ||
+ | return 1 / C; | ||
+ | } | ||
+ | if (x === 10) { | ||
+ | return 10; | ||
+ | } | ||
+ | if ((1 / C) > 10) | ||
+ | return 10 | ||
+ | } | ||
+ | } | ||
+ | // Ausgabe des Wertes x(t) | ||
+ | setInterval(function() { | ||
+ | document.getElementById("x(t)").innerHTML = Math.round((sldA1.Value() * Math.cos(2 * Math.PI * sldF1.Value() * sldT.Value() - 2 * Math.PI * sldPHI1.Value() / 360) + sldA2.Value() * Math.cos(2 * Math.PI * sldF2.Value() * sldT.Value() - 2 * Math.PI * sldPHI2.Value() / | ||
+ | 360)) * 1000) / 1000; | ||
+ | }, 50); | ||
+ | // Ausgabe des Wertes x(t+T_0) | ||
+ | setInterval(function() { | ||
+ | document.getElementById("x(t+T_0)").innerHTML = Math.round((sldA1.Value() * Math.cos(2 * Math.PI * sldF1.Value() * (sldT.Value() + Math.round(getT0() * 1000) / 1000) - sldPHI1.Value()) + sldA2.Value() * Math.cos(2 * Math.PI * sldF2.Value() * (sldT.Value() + | ||
+ | Math.round(getT0() * 1000) / 1000) - sldPHI2.Value())) * 1000) / 1000; | ||
+ | }, 50); | ||
+ | // Ausgabe des Wertes x(t+2T_0) | ||
+ | setInterval(function() { | ||
+ | document.getElementById("x(t+2T_0)").innerHTML = Math.round((sldA1.Value() * Math.cos(2 * Math.PI * sldF1.Value() * (sldT.Value() + 2 * Math.round(getT0() * 1000) / 1000) - sldPHI1.Value()) + sldA2.Value() * Math.cos(2 * Math.PI * sldF2.Value() * (sldT.Value() + | ||
+ | 2 * Math.round(getT0() * 1000) / 1000) - sldPHI2.Value())) * 1000) / 1000; | ||
+ | }, 50); | ||
+ | // Ausgabe des Wertes x_max | ||
+ | setInterval(function() { | ||
+ | var x = new Array(50000); | ||
+ | for (var i = 0; i < 50001; i++) { | ||
+ | x[i] = Math.round((sldA1.Value() * Math.cos(2 * Math.PI * sldF1.Value() * (i / 1000) - 2 * Math.PI * sldPHI1.Value() / 360) + sldA2.Value() * Math.cos(2 * Math.PI * sldF2.Value() * (i / 1000) - 2 * Math.PI * sldPHI2.Value() / 360)) * 1000) / 1000; | ||
+ | } | ||
+ | document.getElementById("x_max").innerHTML = Math.max.apply(Math, x); | ||
+ | }, 50); | ||
}; | }; | ||
// Definition der Funktion zum An- und Ausschalten des Koordinatengitters | // Definition der Funktion zum An- und Ausschalten des Koordinatengitters |
Revision as of 22:11, 18 September 2017
Funktion: $$x(t) = A_1\cdot cos\Big(2\pi f_1\cdot t- \frac{2\pi}{360}\cdot \phi_1\Big)+A_2\cdot cos\Big(2\pi f_2\cdot t- \frac{2\pi}{360}\cdot \phi_2\Big)$$
$x(t)$= $\quad$ | $x(t+ T_0)$= $\quad$ | $x(t+2T_0)$= $\quad$ | $x_{\text{max}}$= $\quad$ | $T_0$= $\quad$ |